Cell structure of microcellular combustible object foamed by supercritical carbon dioxide 被引量：2

Cell structure of microcellular combustible object foamed by supercritical carbon dioxide

下载PDF

导出

摘要 In order to solve the issue that the combustible objects for cased telescoped ammunition (CTA) didn't burn completely during the combustion process, the microcellular combustible objects were foamed with numerous cells in the micron order to improve the combustion performance by the supercritical carbon dioxide (SCeCO2) foaming technology. As the cell structure determined the combustion properties of microcellular combustible objects, the solubility of SCeCO2 dissolved into the combustible objects was obtained from the gravimetric method, and scanning electron microscope (SEM) was applied to characterize the cell structure under various process conditions of solubility, foaming temperature and foaming time. SEM images indicate that the cell diameter of microcellular combustible objects is in the level of 1 mm and the cell density is about 1011 cell,cm^-3. The microcellular combustible objects fabricated by the SCeCO2 foaming technology are smooth and uniform, and the high specific surface area of cell structure can lead to the significant combustion performance of microcellular combustible object for CTA in the future. In order to solve the issue that the combustible objects for cased telescoped ammunition（CTA） didn’t burn completely during the combustion process, the microcellular combustible objects were foamed with numerous cells in the micron order to improve the combustion performance by the supercritical carbon dioxide（SCeCO2） foaming technology. As the cell structure determined the combustion properties of microcellular combustible objects, the solubility of SCeCO2 dissolved into the combustible objects was obtained from the gravimetric method, and scanning electron microscope（SEM） was applied to characterize the cell structure under various process conditions of solubility, foaming temperature and foaming time. SEM images indicate that the cell diameter of microcellular combustible objects is in the level of 1 mm and the cell density is about 1011 cell,cm-3. The microcellular combustible objects fabricated by the SCeCO2 foaming technology are smooth and uniform, and the high specific surface area of cell structure can lead to the significant combustion performance of microcellular combustible object for CTA in the future.

作者 Ya-jun Ding San-jiu Ying Zhong-liang Xiao Xu Wu

机构地区 School of Chemical Engineering

出处《Defence Technology（防务技术）》 SCIE EI CAS CSCD 2019年第3期419-425,共7页 Defence Technology

关键词 CELL structure MICROCELLULAR COMBUSTIBLE OBJECT SOLUBILITY FOAMING temperature FOAMING time Cell structure Microcellular combustible object Solubility Foaming temperature Foaming time

分类号 TJ [兵器科学与技术]

引文网络
相关文献

参考文献4

1张浩,陆欣,余永刚,周彦煌.某口径埋头弹火炮的密封与装药设计[J].兵工学报,2006,27(4):630-633. 被引量：14
2杨伟涛,应三九.CA/RDX复合材料超临界CO_2间歇法微孔发泡研究（英文）[J].火炸药学报,2016,39(2):22-26. 被引量：3
3Jia-gang Wang,Yong-gang Yu,Liang-liang Zhou,Rui Ye.Numerical simulation and optimized design of cased telescoped ammunition interior ballistic[J].Defence Technology（防务技术）,2018,14(2):119-125. 被引量：9
4D.CORRIVEAU,C.FLORIN PETRE.Influence of chamber misalignment on cased telescoped(CT) ammunition accuracy[J].Defence Technology（防务技术）,2016,12(2):117-123. 被引量：8

二级参考文献14

1张浩,周彦煌,林君毅.埋头弹火炮活动药室的组合自紧密封设计[J].火炮发射与控制学报,2005,26(1):38-42. 被引量：9
2张浩,周彦煌.埋头弹火炮零维内弹道模型及计算[J].弹道学报,2005,17(2):80-83. 被引量：11
3张浩,陆欣,余永刚,周彦煌.某口径埋头弹火炮的密封与装药设计[J].兵工学报,2006,27(4):630-633. 被引量：14
4Kalsi M S, Conroy W T, Dietle L, et al. A novel high-pressure rotary shaft seal facilitates in drilling and production equipment,SPE/IDAC 37627[ R], 1997, 3:4 - 6. 被引量：1
5Clive R Woodly. Development of one-dimensional internal ballistics model of a cased telescoped ammunition gun[ C]. Proeedings of the 15th International Symposium on Ballistics, 1995:223-231. 被引量：1
6Shipley PA, Cole BT, Phillips K. Cased telescoped small arms systems.Presented at the Joint armaments forum, exhibition & technologydemonstration, Phoenix, AZ, 12–15 May; 2014. 被引量：1
7Mann FW. The bullet’s flight from powder to target. NewYork, NY: Munn& Company; 1909. 被引量：1
8Murphy CH. Yaw induction by mass asymmetry. J Spacecr Rockets1977;14(8):511–12. 被引量：1
9Ritter JJ. Barrel leade effects on 5.56 mm interior ballistics. In:Proceedings of the 28th international symposium on ballistics, Atlanta,GA, 22–26 September; 2014. 被引量：1
10Bayer RA, Ritter JJ. Measurements of early bullet motion at 5.56 mmand 7.62 mm. In: Proceedings of the 28th international symposium onballistics, Atlanta, GA, 22–26 September; 2014. 被引量：1

共引文献27

1陆欣,张浩,周彦煌,余永刚.埋头弹内弹道过程数值分析[J].南京理工大学学报,2008,32(6):690-694. 被引量：9
2韩铁,袁志华,陈强,胡明,唐双喜,王国军.导气式旋转药室结构研究[J].火炮发射与控制学报,2014,35(4):87-90. 被引量：1
3佟凯,李强.新型埋头弹火炮自动机结构设计与仿真[J].科技创新与生产力,2015(3):41-43. 被引量：3
4王加刚,余永刚,郭飞,周良梁.多参数变化对埋头弹火炮内弹道性能的影响[J].弹道学报,2015,27(2):69-73. 被引量：7
5王加刚,余永刚,曹韩学,周良梁.埋头弹药发射过程药筒力学特性分析[J].应用力学学报,2016,33(4):640-645. 被引量：4
6马慧明,张亚,李世中.弹尾弹射式侵彻数据回收系统设计原理及试验研究[J].弹箭与制导学报,2016,36(5):155-158. 被引量：1
7马慧明,张亚,李世中.弹底火药气体的间隙密封结构性能分析[J].振动与冲击,2017,36(12):140-145. 被引量：4
8王加刚,余永刚,周良梁.埋头弹火炮高效低危害炮口制退器的实验研究[J].兵工学报,2017,38(5):1035-1040. 被引量：6
9杨伟涛,张玉成,刘少武,张远波,王琼林.RDX基可燃材料的热力学性能,非等温反应动力学及安全性研究（英文）[J].火炸药学报,2017,40(2):19-23. 被引量：2
10马慧明,张亚,李世中.弹尾弹射装置间隙密封的火药气体动力学[J].爆炸与冲击,2017,37(5):976-982. 被引量：2

同被引文献13

1李应林,向帮龙,蒋亚静,肖兆新,管蓉.微孔发泡成核理论新进展[J].现代塑料加工应用,2006,18(6):59-61. 被引量：4
2刘艳秋,马忠亮,萧忠良,张续柱.碳纤维对无壳弹药柱力学性能影响的研究[J].火炸药学报,1999,22(3):29-31. 被引量：5
3应三九,徐复铭.发射药超临界发泡微孔制备技术研究[J].兵工学报,2013,34(8):1028-1036. 被引量：11
4Yu-xiang LI,Wei-tao YANG,San-jiu YING.Investigation on the foaming behaviors of NC-based gun propellants[J].Defence Technology（防务技术）,2014,10(3):261-268. 被引量：3
5张邹邹,周敬,杨丽侠,赵宝明,刘来东.温度对粒状发射药动态力学性能的影响[J].火炸药学报,2015,38(2):86-88. 被引量：4
6邹伟伟,郝晓琴,张志勇,党海燕,周伟良.小口径可燃药筒及装药的燃烧性能研究[J].兵工学报,2015,36(8):1423-1429. 被引量：7
7裔璐,堵平,刘琼.一种新型可燃药盒的特性研究[J].含能材料,2016,24(10):990-994. 被引量：7
8张一鸣,丁亚军,罗元香,应三九.分层结构微孔球扁药制备条件对其燃烧性能的影响[J].含能材料,2017,25(3):248-252. 被引量：3
9张硕,丁亚军,应三九.微孔NC/TEGN/RDX复合材料的制备及力学性能[J].含能材料,2019,27(3):210-215. 被引量：5
10解德富,黄振亚,宋亚苹,张成.乙二胺-三乙烯二胺高氯酸盐对高能发射药热分解反应的影响[J].火炸药学报,2020,43(2):208-212. 被引量：4

引证文献2

1刘慧娜,应三九,丁亚军,顾晗.碳纤维增强微孔可燃壳体的制备及性能研究[J].火炸药学报,2021,44(1):96-100. 被引量：1
2郏杭生,崔立宝,丁亚军,李成龙,顾晗,王晓倩.含CL-20的微孔发射药的设计及性能研究[J].爆破器材,2024,53(4):37-44.

二级引证文献1

1郏杭生,崔立宝,丁亚军,李成龙,顾晗,王晓倩.含CL-20的微孔发射药的设计及性能研究[J].爆破器材,2024,53(4):37-44.

1Rui-Zhi Zhang,Ju Chen,Mao-Wei Huang,Jian Zhang,Guo-Qiang Luo,Bao-Zhen Wang,Mei-Juan Li,Qiang Shen,Lian-Meng Zhang.Synthesis and Compressive Response of Microcellular Foams Fabricated from Thermally Expandable Microspheres[J].Chinese Journal of Polymer Science,2019,37(3):279-288. 被引量：3
2黄成潭,陈英,宁荣良,廖超,陈小锋,李文佳.DOE法优化筛选表达胰高血糖素样肽-1融合蛋白的CHO细胞用培养基[J].中国生物制品学杂志,2019,32(2):186-192.
3Dong-wen Xiang,Feng-man Shen,Jia-long Yang,Xin Jiang,Hai-yan Zheng,Qiang-jian Gao,Jia-xin Li.Combustion characteristics of unburned pulverized coal and its reaction kinetics with CO2[J].International Journal of Minerals,Metallurgy and Materials,2019,26(7):811-821. 被引量：3
4Jia-gang Wang,Yong-gang Yu,Liang-liang Zhou,Rui Ye.Numerical simulation and optimized design of cased telescoped ammunition interior ballistic[J].Defence Technology（防务技术）,2018,14(2):119-125. 被引量：9
5戴微,金百锁.逻辑回归模型的Smooth LASSO及Spline LASSO变量选择[J].应用概率统计,2019,35(3):292-304. 被引量：2
6Yanjie Wu,Changfa Xiao,Hailiang Liu,Qinglin Huang.Fabrication and characterization of novel foaming polyurethane hollow fiber membrane[J].Chinese Journal of Chemical Engineering,2019,27(4):935-943. 被引量：1
7Houkang CAO,Boting XI,Simao HUANG,Xiaohua PANG,Kefeng ZHANG.Optimization of Extraction Process of Total Flavonoids from Akebia trifoliata (Thunb.) Koidz. by Central Composite Design-Response Surface Methodology[J].Medicinal Plant,2017,8(2):15-18. 被引量：4
8Shaosen Ma,Weizhong Chen,Wusheng Zhao.Mechanical properties and associated seismic isolation effects of foamed concrete layer in rock tunnel[J].Journal of Rock Mechanics and Geotechnical Engineering,2019,11(1):159-171. 被引量：15
9Yanwei GUO,Cong NIE,Xueqin GUAN,Jie ZHANG,Guiheng YANG.Study on Brewing Characteristics of High α-acid and High β-acid Hops[J].Agricultural Biotechnology,2019,8(2):185-187.
10Abdul Rahim Risal,Muhammad A.Manan,Nurudeen Yekeen,Nur Bashirah Azli,Ali Mohamed Samin,Xin Kun Tan.Experimental investigation of enhancement of carbon dioxide foam stability, pore plugging, and oil recovery in the presence of silica nanoparticles[J].Petroleum Science,2019,16(2):344-356. 被引量：5

Defence Technology（防务技术）

2019年第3期

浏览历史

内容加载中请稍等...